JP2004130225A - Electrolytic water producing apparatus - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To operate a preventing means, which prevents the propagation of bacteria periodically and automatically to dispense with the new operation of the preventing means at the time of resumption of electrolytic operation in an electrolytic water producing apparatus equipped with an electrolytic cell 11, a supply pipeline 12 for supplying water to be electrolyzed to the respective electrolytic chambers of the electrolytic cell 11 and extraction pipelines 13a and 13b for respectively extracting electrically produced water components made in the respective electrolytic chambers. <P>SOLUTION: The electrolytic water producing apparatus is equipped with a washing means having the washing pipelines 12a and 12b respectively communicating with the upstream leading end part and downstream extraction port of the electrolytically produced alkaline water extraction pipeline 13a. The washing means has a function for supplying washing water to the washing pipelines 12a and 12b when the extraction from the electrolytically produced alkaline water extraction pipe line 13a is stopped for a predetermined time to extract stagnating water and washing water from the electrolytically produced alkaline water extraction pipe line 13a. <P>COPYRIGHT: (C)2004,JPO

Description

[0001]
TECHNICAL FIELD OF THE INVENTION
The present invention relates to an electrolyzed water generation device.
[0002]
[Prior art]
As one type of the electrolyzed water generating apparatus, a diaphragm electrolyzer, a supply pipe for supplying the electrolyzed water to each electrolyzer of the electrolyzer, and each electrolyzed water generated in each electrolyzer of the electrolyzer. There is an electrolyzed water generation device of a type including a pair of extraction pipes for extracting each. In this type of electrolyzed water generator, alkali water is generated in one electrolysis chamber of the electrolyzer (electrolytically generated water), and acidic water is generated in the other electrolyzer of the electrolyzer (electrolytically generated acid). water). The generated electrolytically generated water is extracted through one extraction line (referred to as an electrolytically generated water extraction line), and the generated electrolytically generated acidic water is extracted through the other extraction line (electrolytically generated acidic water). (Referred to as a water extraction conduit).
[0003]
However, in the electrolyzed water generating apparatus of this type, when the electrolyzed alkaline water is stagnant for a long time in the electrolyzed alkaline water extraction conduit, bacteria and bacteria are discharged from the downstream extraction port of the extraction conduit. Is easily invaded and propagated, and the propagation of bacteria may gradually expand from the extraction port into the extraction conduit. For this reason, it is not sanitary for bacteria to start from the downstream extraction port of the electrolytically produced alkaline water extraction pipe and start to propagate, and in the electrolyzed water generation apparatus of this type, the electrolytically generated alkaline water extraction pipe is not preferable. It is required to provide a preventive means for preventing the invasion of bacteria into the inside and the propagation of bacteria due to the bacteria in the extraction line. In order to cope with this demand, an electrolyzed water generation device provided with the prevention means has been proposed (for example, see Patent Document 1).
[0004]
The electrolyzed water generation device proposed in the above-mentioned Patent Document 1 is an electrolyzed water generation device provided with a water purification cartridge for purifying water before supplying tap water, which is water to be electrolyzed, to a diaphragm electrolyzer. Then, as means for preventing the propagation of germicides, a bypass passage for supplying tap water to the diaphragm electrolysis tank bypassing the water purification cartridge and a water passage for the tap water are switched between the water purification cartridge side and the bypass passage side. A switching means is provided, and a control means for stopping power supply to each electrode of the diaphragm electrolyzer in accordance with switching of the water passage to the bypass passage side. In the electrolyzed water generator, when the water passage of the tap water is switched to the water purification cartridge side by manually operating the switching means, the electrolysis operation is stopped, and the residual chlorine that is not subjected to the purification treatment to the diaphragm electrolytic cell is removed. The supplied tap water is supplied, and the water passage on the downstream side of the water purification cartridge is sterilized by the tap water containing residual chlorine.
[0005]
[Patent Document 1]
JP-A-7-16570 (pages 1 and 2; FIG. 1)
[0006]
[Problems to be solved by the invention]
By the way, the means for preventing the propagation of germicides in the electrolyzed water generating apparatus proposed in Patent Document 1 described above is operated by manual switching operation of the switching means during the electrolysis operation, and the switching means is operated manually. If it is forgotten, it does not operate, and does not have the effect of preventing the propagation of germicides. Further, even if the switching operation by the switching unit is performed exactly immediately before the end of the electrolysis operation of the electrolyzed water generating device, if the electrolysis operation is stopped for a long time, the propagation prevention unit does not operate during this time. Therefore, there is a possibility that germicidal organisms may propagate. Therefore, when restarting the electrolysis operation, the switching means is switched again to operate the means for preventing the propagation of germicidals, and after a predetermined time has elapsed, the switching means is switched again to reverse the propagation of the germs. The operation of the prevention means must be stopped and the electrolytic operation must be started.
[0007]
Accordingly, an object of the present invention is to provide a diaphragm electrolyzer, a supply pipe for supplying water to be electrolyzed to each electrolyzer of the electrolyzer, and each electrolyzed water generated in each electrolyzer of the electrolyzer. In an electrolyzed water generating apparatus of a type having a pair of extraction pipes for extraction, a means (washing means) for preventing propagation of germicidal substances is periodically and automatically operated, and electrolysis after a prolonged stop of electrolysis operation. Another object of the present invention is to eliminate the necessity of a new operation of a means for preventing the propagation of germicides (cleaning means) when restarting the operation.
[0008]
[Means for Solving the Problems]
The present invention relates to an electrolyzed water generating apparatus, and includes a diaphragm electrolyzer, a supply pipe for supplying water to be electrolyzed to each electrolyzer of the electrolyzer, and each electrolyzer generated in each electrolyzer of the electrolyzer. The present invention is applied to an electrolyzed water generating apparatus having a pair of extraction pipes for extracting water, respectively.
[0009]
Thus, in the first electrolyzed water generating apparatus according to the present invention, the cleaning apparatus having the cleaning pipe communicating with the upstream end of the electrolytically generated alkaline water extraction pipe and the cleaning pipe communicating with the downstream extraction port. Means for supplying washing water to each of the washing conduits when extraction from the electrolytically produced alkaline water extraction conduit is stopped for a predetermined time, wherein the electrolytically produced alkaline water extraction conduit is provided. Characterized by a function of first extracting the remaining water and then extracting the washing water.
[0010]
Further, in the second electrolyzed water generating apparatus according to the present invention, the cleaning means having a cleaning pipe communicating with the upstream end of the electrolytically generated alkaline water extraction pipe and a cleaning pipe communicating with the downstream extraction port. The washing means, when the extraction from the electrolytically generated alkaline water extraction pipeline has been stopped for a predetermined time, supplies the cleaning water to each of the cleaning pipelines, the electrolytically generated alkaline water extraction pipeline It is characterized by having a function of extracting the retained water and the washing water simultaneously and extracting the washing water longer.
[0011]
In each of the electrolyzed water generating apparatuses according to the present invention, the standby time is a time during which extraction from the electrolytically generated alkaline water extraction pipe is stopped for a predetermined time, and the standby time is short in the daytime and long in the nighttime. Can be set. Further, the cleaning means may be configured to include a flow rate sensor of the cleaning water flowing through each of the cleaning conduits. In each of the electrolyzed water generating apparatuses according to the present invention, the raw water to be electrolyzed may be used as general water, and the cleaning unit may use one or both of the general water and the electrolyzed water as cleaning water. it can.
[0012]
[Action and Effect of the Invention]
In the first electrolyzed water generating apparatus according to the present invention, the washing means supplies the washing water to each of the washing pipes when the extraction from the electrolyzed alkaline water extraction pipe is stopped for a predetermined time. It has the function of first extracting the retained water in the formed alkaline water extraction line and then extracting the wash water.
[0013]
For this reason, by the washing means, until the end of the standby time of the electrolysis operation, the accumulated water in the electrolytically generated alkaline water extraction pipe is periodically replaced with the wash water, and the extraction port of the extraction pipe is extracted. By washing the cleaning section with washing water, it is possible to prevent the growth of bacteria in the electrolytically-generated alkaline water extraction conduit and to wait in a state where the cleaning is maintained until the start of the electrolytic operation.
[0014]
Further, in the second electrolyzed water generation apparatus according to the present invention, the washing means supplies the washing water to each washing pipeline when the extraction from the electrolytically produced alkaline water extraction pipeline is stopped for a predetermined time. It has the function of simultaneously extracting the retained water and the washing water in the electrolytically generated alkaline water extraction pipe and extracting the washing water for a longer time.
[0015]
For this reason, according to the second electrolyzed water generator according to the present invention, as in the first electrolyzed water generator according to the present invention, the cleaning means periodically performs until the end of the standby time of the electrolysis operation. First, the accumulated water in the electrolytically generated alkaline water extraction line is replaced with washing water, and the extraction port of the extraction line is washed with cleaning water to remove bacteria in the electrolytically generated alkaline water extraction line. The breeding of the species can be prevented, and the cleaning can be kept on standby until the start of the electrolytic operation.
[0016]
Thus, in the second electrolyzed water generator according to the present invention, in particular, the replacement of the stagnant water in the electrolytically generated alkaline water extraction pipe with the wash water and the cleaning water at the extraction port of the extraction pipe are used. Since the washing and the washing are performed in synchronization, if the electrolytically generated alkaline water extraction line is long, the retained water in the electrolytically generated alkaline water extraction line is replaced with cleaning water and the extraction port of the extraction line is replaced with the washing water. There is an advantage that the time required for cleaning with the cleaning water can be reduced in a shorter time than the cleaning means employed in the first electrolyzed water generator.
[0017]
In each of the electrolyzed water generating devices according to the present invention, the time during which extraction from the electrolytically generated alkaline water extraction pipe is stopped for a predetermined time is set as a standby time, and the standby time is set to be short in the daytime and long in the nighttime. You can make it. In the electrolyzed water generation device, the frequency of use during the day tends to be unsanitary, and the frequency of use during the night is less hygienic than the daytime, and the number of times of nighttime washing that is more sanitary is reduced. No problem. According to the cleaning means, there is an advantage that such a cleaning mode can be adopted.
[0018]
Further, in each of the electrolyzed water generating apparatuses according to the present invention, the washing means may be configured to include a flow rate sensor for detecting a flow rate of the washing water flowing through each washing pipeline. According to the washing means, the replacement of the retained water in the electrolytically generated alkaline water extraction pipe with the wash water and the amount of wash water required for washing the extraction port of the extraction pipe with the wash water are accurately confirmed, The amount of washing water required for replacement and washing can be managed without waste. In each electrolyzed water generating apparatus according to the present invention, when the raw water to be electrolyzed is general water, the raw water and / or the electrolyzed water can be used as the washing water. Therefore, the washing means of the present invention can be more advantageously applied to an electrolyzed water generating apparatus of a type in which water to be electrolyzed using general water as raw water is subjected to diaphragm electrolysis.
[0019]
BEST MODE FOR CARRYING OUT THE INVENTION
The present invention provides a diaphragm electrolyzer, a supply pipe for supplying water to be electrolyzed to each electrolyzer of the electrolyzer, and a pair of electrolyzed water generated in each electrolyzer of the electrolyzer. An electrolyzed water generating apparatus having an extraction pipe, wherein the electrolyzed water generating apparatus includes a washing unit. 1 to 4 show an electrolyzed water generating apparatus according to each embodiment of the present invention. The electrolyzed water generating apparatuses according to the respective embodiments have different cleaning means, but have basically the same configuration except for the cleaning means.
[0020]
In the following, the electrolyzed water generator according to the first embodiment shown in FIG. 1 is a first electrolyzed water generator, the electrolyzed water generator according to the second embodiment shown in FIG. 2 is a second electrolyzed water generator, and FIG. The electrolyzed water generator according to the third embodiment shown in FIG. 3 is referred to as a third electrolyzed water generator, and the electrolyzed water generator according to the fourth embodiment shown in FIG. 4 is referred to as a fourth electrolyzed water generator.
[0021]
The first electrolyzed water generator uses tap water as raw water to be electrolyzed, and supplies electrolyzed water to the diaphragm electrolyzer 11 and the electrolysis chambers R1 and R2 of the electrolyzer 11 as shown in FIG. Supply line 12, a pair of extraction lines 13a and 13b for extracting each electrolyzed water generated in each of the electrolysis chambers R1 and R2 of the electrolysis tank 11, and a water purifier 14, and the A control device 20 for controlling operation is provided.
[0022]
The supply line 12 branches into a main line 12a and a bypass line 12b. The main conduit 12a is provided with an electrolytic cell 11 and a water purifier 14 upstream thereof. Further, a pressure reducing valve 15a is interposed in the supply line 12 upstream of the branch portion, and a pressure reducing valve 15b is interposed in the main line 12a. The tap water is supplied to the water purifier 14 through the main pipe 12a, purified, becomes water to be electrolyzed, and supplied to each of the electrolysis chambers R1 and R2 of the electrolysis tank 11.
[0023]
The bypass pipe 12b branches off on the upstream side of the water purifier 14 in the main pipe 12a and is a downstream end of the first extraction pipe 13a in a state of bypassing the water purifier 14 and the electrolytic cell 11. It is connected to the extraction port. A pressure reducing valve 15c is provided at an intermediate portion of the bypass pipe 12b. The tap water supplied to the bypass pipe 12b is supplied to an extraction port which is a downstream end of the first extraction pipe 13a.
[0024]
Among the extraction pipes 13a and 13b, the first extraction pipe 13a is connected to the cathode-side electrolysis chamber R1 of the electrolytic cell 11, and is configured as a dedicated extraction pipe for extracting the electrolyzed alkaline water. The second extraction line 13b is connected to the anode-side electrolysis chamber R2 of the electrolytic cell 11, and is configured as a dedicated extraction line for extracting the electrolyzed acidic water. The first extraction line 13a is provided with an electromagnetic opening / closing first extraction valve 16a, and the bypass line 12b is provided with an electromagnetic opening / closing second extraction valve 16b.
[0025]
In the first electrolyzed water generator, the washing means is provided in the main pipe 12a, the bypass pipe 12b, the extraction valve 16a provided in the first extraction pipe 13a, and the bypass pipe 12b. It is composed of an extraction valve 16b and the like. The washing means employs tap water and electrolyzed water obtained by purifying tap water with a water purifier 14 as wash water.
[0026]
The control device 20 controls the operation of the electrolyzed water generation device, and includes an MPU (microprocessor), a timer, and a drive circuit. The MPU includes a CPU and a memory, and the memory holds a control program and data for controlling the operation of the electrolyzed water generation device.
[0027]
The control device 20 includes an automatic extraction switch 21a and a manual extraction switch 21b disposed on the control panel 20a of the electrolyzed water generator, an extraction switch 22a for cleaning water (tap water), and an automatic extraction switch for cleaning water. The cleaning switch 22b is connected. These switches 21a, 21b, 22a, and 22b are for outputting various operation selection commands to the control device 20 in order to select the electrolyzed water generator, which is turned on, to an operation state corresponding to the purpose. .
[0028]
Among the switches, the automatic extraction switch 21a outputs a signal for selecting an electrolysis operation state to the control device 20, and the control device 20 controls the electrolysis operation based on the output signal under a set condition. Then, a predetermined amount of electrolytically generated alkaline water is extracted from the extraction port through the first extraction line 13a. In the electrolysis operation control, the first extraction valve 16a is controlled to be open for a predetermined time. As a result, the consumer can obtain a predetermined amount of the electrolyzed alkaline water set by the control program for the electrolysis operation.
[0029]
The manual extraction switch 21b compensates for or adds to the shortage of the amount of electrolyzed alkaline water extracted during the automatic electrolysis operation by turning on the automatic extraction switch 21a, and is performed only when the manual extraction switch 21b is turned on. The electrolysis operation of the electrolyzed water generator is controlled. In the electrolysis operation control, the first extraction valve 16a is controlled to be open while the manual extraction switch 21b is being turned on. As a result, the consumer can obtain a desired amount of electrolyzed alkaline water by adding a desired amount of electrolyzed alkaline water to the amount of electrolyzed alkaline water obtained during the automatic electrolysis operation.
[0030]
The washing water extraction switch 22a outputs a signal for selecting an operation state for extracting washing water to the control device 20, and the control device 20 sets the washing water extraction operation based on the output signal. Under controlled conditions, tap water as washing water is extracted from the extraction port of the first extraction pipe 13a through the bypass pipe 12b. In the washing water extraction operation control, the opening of the second extraction valve 16b is controlled while the washing water extraction switch 22a is being turned on. As a result, the consumer can obtain tap water for cleaning, and can use the tap water to wash and clean the brought container before the electrolytic operation.
[0031]
The automatic cleaning switch 22b outputs a signal for selecting a cleaning operation state to the control device 20, and the control device 20 controls the cleaning operation based on the output signal under a set condition to supply tap water. The purified electrolyzed water is supplied as washing water to each of the electrolysis chambers R1 and R2 of the electrolyzer 11 through the main pipe 12a. The supplied water to be electrolyzed is extracted from each of the electrolysis chambers R1 and R2 of each of the electrolysis tanks 11 through a first extraction pipe 13a and a second extraction pipe 13b. Also, synchronously or selectively, tap water is supplied as washing water to the bypass pipe 12b to be extracted from the extraction port of the first extraction pipe 13a. In the washing operation, the first extraction valve 16a is controlled to be open for a predetermined time, and the second extraction valve 16b is controlled to be open for a predetermined time that is the same as or different from the set first extraction valve 16a. .
[0032]
The control device 20 includes an electrolysis control program, a washing water extraction control program, and a washing operation control program, and the time condition in each control program can be set as desired by operating a timer provided in the control panel 20a. It is configured to be set to.
[0033]
In the control device 20, an operation selection command signal output by turning on each of the switches 21a, 21b, 22a, 22b is fetched via an interface, and the MPU controls the electrolyzed water generation device based on the fetched command signals. A state to be operated is determined, and a command signal corresponding to a mode to be operated is output to the drive circuit via the interface. The drive circuit controls the opening and closing of each extraction valve 16a, 16b based on a command signal from the MPU, and controls the application of current to each electrode arranged in each electrolysis chamber R1, R2 of the electrolysis tank 11. Then, control such as electrolysis operation and cleaning operation is performed.
[0034]
The cleaning means of the electrolyzed water generation device according to the present invention is characterized by a control program for controlling a cleaning operation provided in the control device 20, and a microcomputer constituting the control device 20 executes the control program according to FIG. The processing is executed based on the flowchart shown in any one of FIGS.
[0035]
In the first electrolyzed water generator, the washing means is constituted by a main pipe 12a, a bypass pipe 12b, both extraction valves 16a, 16b, and the like. Until the end of the standby time of the operation, the tap water is periodically supplied to the electrolytic cell 11 through the water purifier 14 through the main pipe 12a, and the first extraction pipe is supplied through the cathode chamber R1 of the electrolytic tank 11. 13a, and tap water can be supplied to the extraction port of the first extraction pipe 13a through the bypass pipe 12b.
[0036]
Thus, according to the washing means, the retained water in the first extraction pipe 13a is replaced with the electrolyzed water, and the extraction port of the first extraction pipe 13a is washed with tap water to perform the first extraction. It prevents bacteria from growing in the pipe 13a, and keeps a clean state until the electrolysis operation is started. Depending on the execution of the control program during this time, the water remaining in the second extraction pipe 13b is replaced with the electrolyzed water.
[0037]
The second electrolyzed water generating apparatus according to the present invention uses tap water as raw water to be electrolyzed, and as shown in FIG. A supply pipe 12 for supplying electrolyzed water, a pair of extraction pipes 13a and 13b for extracting each electrolyzed water generated in each of the electrolysis chambers R1 and R2 of the electrolyzer 11 and a water purifier 14 are provided. A control device 20 for controlling the operation of the water generator is provided, and the configuration is the same as the first electrolyzed water generator shown in FIG.
[0038]
Thus, the second electrolyzed water generator does not include the bypass line 12b and the second extraction valve 16b that constitute the first electrolyzed water generator, and instead includes the second extraction line 13b and the second extraction line 13b. There is provided a washing pipe 12c connecting the first extraction pipe 13a, and an electromagnetic switching valve 16c which is a three-way switching valve interposed at a portion where the second extraction pipe 13b and the washing pipe 12c are branched. The switching valve 16c is switched by the control device 20, and controls the outflow direction of the outflow water from the anode chamber R2 side of the electrolytic cell 11.
[0039]
Therefore, in the second electrolyzed water generator, the washing means is constituted by the main pipe 12a, the washing pipe 12c, the extraction valve 16a, the switching valve 16c interposed at the branch of the washing pipe 12c, and the like. By executing the control program of the control device 20, the tap water is periodically supplied to the electrolytic cell 11 through the water purifier 14 through the main pipe 12a until the end of the standby time of the electrolytic operation. To the first extraction line 13a through the cathode chamber R1 of the electrolytic cell 11, and through the anode chamber R2 of the electrolytic cell 11 to the second extraction line 13b, the washing line 12c and the first extraction line 13a. Can be supplied to the extraction port.
[0040]
Thus, according to the cleaning means, the retained water in the first extraction pipe 13a is replaced with the electrolyzed water, and the extraction port of the first extraction pipe 13a is washed with the electrolyzed water, and the first extraction pipe 13a is washed with the electrolyzed water. Bacteria are prevented from growing in the extraction conduit 13a, and a standby state is maintained until the electrolysis operation is started. Depending on the execution of the control program during this time, the water remaining in the second extraction pipe 13b is replaced with the electrolyzed water.
[0041]
The third electrolyzed water generating apparatus according to the present invention uses tap water as raw water to be electrolyzed, and as shown in FIG. A supply pipe 12 for supplying electrolyzed water, a pair of extraction pipes 13a and 13b for extracting each electrolyzed water generated in each of the electrolysis chambers R1 and R2 of the electrolyzer 11 and a water purifier 14 are provided. A control device 20 for controlling the operation of the water generator is provided, and the configuration is the same as the first electrolyzed water generator shown in FIG.
[0042]
Thus, in the third electrolyzed water generating apparatus, the flow rate sensor 17 is interposed on the supply pipe 12 at the upstream of the branch portion and at the downstream of the pressure reducing valve 15a. Therefore, in the third electrolyzed water generating apparatus, the washing means is constituted by the main line 12a, the bypass line 12b, the flow sensor 17, the two extraction valves 16a, 16b, and the like. By the execution of the program, until the end of the standby time of the electrolysis operation, the tap water is periodically supplied to the electrolysis tank 11 through the water purifier 14 through the main pipe 12a, and the cathode chamber R1 of the electrolysis tank 11 is opened. After that, the water can be supplied to the first extraction pipe 13a and the tap water can be supplied to the extraction port of the first extraction pipe 13a through the bypass pipe 12b.
[0043]
Thus, according to the washing means, the retained water in the first extraction pipe 13a is replaced with the electrolyzed water, and the extraction port of the first extraction pipe 13a is washed with tap water to perform the first extraction. Bacteria are prevented from growing in the pipe 13a, and a clean state is maintained until the electrolysis operation is started.
[0044]
In addition, since the washing means is provided with the flow rate sensor 17 in particular, the electrolyzed water (wash water) supplied to the first extraction pipe 13a through the main pipe 12a and the second extraction water through the bypass pipe. The supply flow rate of tap water (wash water) to be supplied to the pipe 13b can be accurately checked as a single unit, and the amount of wash water required for washing can be managed without waste. In the cleaning means, by executing the control program during this time, the water remaining in the second extraction pipe 13b is replaced with the electrolyzed water.
[0045]
The fourth electrolyzed water generation apparatus according to the present invention uses tap water as raw water to be electrolyzed, and as shown in FIG. A supply pipe 12 for supplying electrolyzed water, a pair of extraction pipes 13a and 13b for extracting each electrolyzed water generated in each of the electrolysis chambers R1 and R2 of the electrolyzer 11 and a water purifier 14 are provided. A control device 20 for controlling the operation of the water generating device is provided. This configuration is the same as that of the first electrolyzed water generator shown in FIG.
[0046]
Thus, in the fourth electrolyzed water generator, a flow sensor is provided similarly to the third electrolyzed water generator, but unlike the third electrolyzed water generator, a pair of flow sensors (flow sensors 17a, 17b) is provided. Have. One flow sensor 17a is interposed in the main line 12a forming the supply line 12, and the other flow sensor 17b is interposed in the bypass line 12b forming the supply line 12.
[0047]
Therefore, in the fourth electrolyzed water generator, the washing means is constituted by the main pipe 12a, the bypass pipe 12b, the two extraction valves 16a and 16b, the flow sensors 17a and 17b, and the like. Until the end of the standby time of the electrolysis operation, the tap water is periodically supplied to the electrolysis tank 11 through the water purifier 14 through the main pipe 12a by the execution of the control program having the electrolysis operation. R1 can be supplied to the first extraction pipe 13a, and tap water can be supplied to the extraction port of the first extraction pipe 13a through the bypass pipe 12b.
[0048]
Thus, according to the washing means, the retained water in the first extraction pipe 13a is replaced with the electrolyzed water, and the extraction port of the first extraction pipe 13a is washed with tap water to perform the first extraction. It prevents bacteria from growing in the pipe 13a, and keeps a clean state until the electrolysis operation is started.
[0049]
In addition, in the washing means, in particular, since both the main line 12a and the bypass line 12b are provided with the flow rate sensors 17a and 17b, respectively, the supply to the first extraction line 13a through the main line 12a is performed. The supply flow rates of the electrolytic water (wash water) and the tap water (wash water) to be supplied to the second extraction pipe 13b through the bypass pipe 12b can be accurately confirmed independently of each other, and the cleaning required for cleaning can be performed. The amount of water can be managed without waste. In the cleaning means, by executing the control program during this time, the water remaining in the second extraction pipe 13b is replaced with the electrolyzed water.
[0050]
Each of the above electrolyzed water generating apparatuses is intended to supply the electrolyzed alkaline water to the consumer. The control panel 20a in each electrolyzed water generating apparatus includes a control program for controlling the electrolysis operation and a control program for controlling the cleaning operation. When each switch arranged on the control panel 20a is turned on, the selected switch is selected. The operation of the electrolyzed water generator is controlled according to the purpose of the above.
[0051]
That is, the control panel 20a is provided with an automatic extraction switch 21a, a manual extraction switch 21b, a washing water extraction switch 22a, and an automatic washing switch 22b, and the control device 20 operates when the automatic extraction switch 21a is turned on. Controls the normal electrolysis operation for a set predetermined time, and when the manual extraction switch 21b is turned on, controls the normal electrolysis operation until the manual extraction switch 21b is turned off. When the washing water extraction switch 22a is turned on, the washing operation is controlled while the washing water extraction switch 22a is turned on. When the automatic washing switch 22b is turned on, the setting is performed. A predetermined cleaning operation is controlled.
[0052]
The present invention has a feature in a cleaning control program executed when the automatic cleaning switch 22b is turned on. The control device 20 has three types of programs executed based on the flowcharts shown in FIGS. Cleaning control program. The first cleaning control program is executed based on the flowchart shown in FIG. 5, the second cleaning control program is executed based on the flowchart shown in FIG. 6, and the third cleaning control program is executed based on FIG. It is executed based on the flowchart shown in FIG.
[0053]
The microcomputer constituting the control device 20 operates by turning on the automatic cleaning switch 22b, and starts execution of the first cleaning control program. In the first cleaning control program, for example, the standby time T until the start of cleaning is set to 2 hours, and the extraction time of the retained water (including the electrolyzed alkaline water and the electrolyzed water) from the first extraction line 13a is set. Is set to 10 seconds, and the extraction time of tap water (wash water) from the second extraction conduit 13b is set to 10 seconds. In step 101, the microcomputer sets a timer to start measuring the standby time. In step 102, the microcomputer determines whether or not water is extracted from the extraction port of the first extraction pipe 13a. If it is determined that there is extraction water from the extraction port of the road 13a, the program proceeds to step 106, where the measurement of the standby time is stopped and the timer is reset.
[0054]
If the microcomputer determines in step 102 that there is no extraction water from the extraction port of the first extraction conduit 13a, the microcomputer advances the program to step 103. It is determined whether time T (two hours) has been reached. If the microcomputer determines in step 103 that the standby time has not reached the predetermined time T, the microcomputer returns the program to step 102 to execute the program, and determines that the standby time has reached the predetermined time T. If so, the program proceeds to step 104.
[0055]
In step 104, the microcomputer opens the first extraction valve 16a for a predetermined time (10 seconds), supplies tap water through the water purifier 14 through the main line 12a, and removes the retained water in the first extraction line 13a. Extract for a predetermined time (10 seconds). Next, in step 105, the microcomputer opens the second extraction valve 16b for a predetermined time (10 seconds), supplies tap water through the bypass line 12c, and supplies tap water through the extraction port of the first extraction line 13a. Is extracted for a predetermined time (10 seconds). Thereafter, in step 106, the microcomputer stops measuring the standby time and resets the timer, and ends the cleaning when the predetermined time T has elapsed. The microcomputer circulates and executes the cleaning control program.
[0056]
FIG. 6 is a flowchart for executing the second cleaning control program. The second cleaning control program is suitable for a case where the flowing water path from the supply pipe 12 to the extraction port of the first extraction pipe 13a is long, and the first cleaning control program is provided to the electrolyzed water generating apparatus of the long flowing water path. The cleaning time can be reduced as compared with the case where the control program is adopted.
[0057]
The second cleaning control program is characterized in that the retained water in the first extraction pipe 13a is replaced with electrolyzed water (wash water), and the extraction port of the extraction pipe 13a is washed with tap water (wash water). The supply of tap water is performed simultaneously with the main pipe 12a and the bypass pipe 12b, and the supply to the main pipe 12a is slightly faster and the supply to the bypass pipe 12b is performed. Is stopped slightly later.
[0058]
Thereby, in the electrolyzed water generating apparatus in which the flowing water path from the supply pipe 12 to the extraction port of the first extraction pipe 13a is long, the cleaning time can be significantly reduced. In the cleaning control program, for example, the opening time t1 of the first extraction valve 16a is set to 1 minute, and the opening time t2 of the second extraction valve 16b is set to 1 minute and 3 seconds. Further, the standby time T until the start of cleaning is set to 2 hours.
[0059]
In the execution of the cleaning control program, the microcomputer sets a timer at step 111 to start measuring a standby time, and determines at step 112 whether water is extracted from the extraction port of the first extraction pipe 13a. If it is determined that extraction water is to be extracted from the extraction port of the first extraction pipe 13a, the program proceeds to step 119, in which the measurement of the standby time is stopped and the timer is stopped. Reset.
[0060]
If the microcomputer determines in step 112 that there is no extraction water from the extraction port of the first extraction pipe 13a, the microcomputer advances the program to step 113. It is determined whether time T (two hours) has been reached. If the microcomputer determines in step 113 that the standby time has not reached the predetermined time T, the microcomputer returns the program to step 112 to execute the program, and determines that the standby time has reached the predetermined time T. If so, the program proceeds to step 114.
[0061]
In step 114, the microcomputer opens the first and second extraction valves 16a and 16b to supply tap water through the main line 12a and the bypass line 12b. In steps 115 and 116, the microcomputer extracts the first extraction line. The accumulated water in the passage 13a is extracted for a predetermined time t1 (1 minute), and in steps 117 and 118, tap water is extracted for a predetermined time t2 (1 minute and 3 seconds) through the bypass pipe 12c. Thereafter, in step 119, the microcomputer stops measuring the standby time and resets the timer, and ends the cleaning when the predetermined time T has elapsed. The microcomputer circulates and executes the cleaning control program.
[0062]
The third cleaning control program is for daytime cleaning, and the frequency of daytime cleaning is assumed on the assumption that the degree of contamination of the extraction port of the first extraction conduit 13a will be worse in the daytime than in the nighttime. The feature is that the number was increased compared to nighttime. In the third cleaning control program, the cleaning of the extraction port of the first extraction conduit 13a is added during the set standby time T (for example, 2 hours), and is, for example, half of the set time. At the time (1 hour) after the passage of T1, tap water (wash water) is supplied to the first extraction line 13a through the bypass line 12b and extracted from the extraction hole of the first extraction line 13a. For cleaning.
[0063]
In the execution of the cleaning control program, the microcomputer sets a timer at step 121 to start measuring the standby time, and determines at step 122 whether water is extracted from the extraction port of the first extraction pipe 13a. If it is determined that the extraction water is to be extracted from the extraction port of the first extraction pipe 13a, the program proceeds to step 131, and in step 131, the measurement of the standby time is stopped and the timer is stopped. Reset.
[0064]
If the microcomputer determines in step 122 that there is no extraction water from the extraction port of the first extraction pipe 13a, the microcomputer advances the program to step 123. It is determined whether or not time T1 (one hour) has been reached. If the microcomputer determines in step 123 that the standby time has not reached the predetermined time T1, the microcomputer returns the program to step 122 to execute the program, and determines that the standby time has reached the predetermined time T1. If so, the program proceeds to step 124. In step 124, the microcomputer opens the second extraction valve 16b to supply tap water through the bypass line 12b. In steps 125 and 126, the microcomputer supplies tap water through the bypass line 12b for a predetermined time t1 (10 seconds). )Extract.
[0065]
Next, in step 127, the microcomputer determines whether or not extraction water has been extracted from the extraction port of the first extraction pipe 13a. If it is determined that there is extraction, the program proceeds to step 131. In step 131, the measurement of the standby time is stopped and the timer is reset. When the microcomputer determines in step 127 that there is no extraction water from the extraction port of the first extraction conduit 13a, the microcomputer advances the program to step 128 and waits for the program in step 128. It is determined whether or not the time has reached a predetermined time T (two hours). If the microcomputer determines in step 128 that the standby time has not reached the predetermined time T, the microcomputer returns the program to step 127 to execute the program, and determines that the standby time has reached the predetermined time T. If so, the program proceeds to step 129.
[0066]
In step 129, the microcomputer opens the first extraction valve 16a for a predetermined time (10 seconds), supplies tap water through the water purifier 14 through the main line 12a, and removes the retained water in the first extraction line 13a. Extract for a predetermined time (10 seconds). Next, in step 130, the microcomputer opens the second extraction valve 16b for a predetermined time (10 seconds), supplies tap water through the bypass line 12c, and supplies tap water through the extraction port of the first extraction line 13a. Is extracted for a predetermined time (10 seconds). Thereafter, in step 131, the microcomputer stops measuring the standby time and resets the timer, and ends the cleaning when the predetermined time T has elapsed. The microcomputer circulates and executes the cleaning control program.
[Brief description of the drawings]
FIG. 1 is a schematic configuration diagram schematically showing an entire first electrolyzed water generation device according to the present invention.
FIG. 2 is a schematic configuration diagram schematically showing the entire second electrolyzed water generation device according to the present invention.
FIG. 3 is a schematic configuration diagram schematically showing the entire third electrolyzed water generation device according to the present invention.
FIG. 4 is a schematic configuration diagram schematically showing the entire third electrolyzed water generation device according to the present invention.
FIG. 5 is a flowchart for executing a first cleaning control program included in the electrolytic water generation device according to the present invention.
FIG. 6 is a flowchart for executing a second cleaning control program of the electrolytic water generation device according to the present invention.
FIG. 7 is a flowchart for executing a third cleaning control program included in the electrolyzed water generation device according to the present invention.
[Explanation of symbols]
11 electrolytic cell, 12 supply line, 12a main line, 12b bypass line, 12c washing line, 13a first extraction line (electrolysis generated alkaline water extraction line), 13b second Extraction line (electrolytically generated acidic water extraction line), 14: water purifier, 15a, 15b, 15c: pressure reducing valve, 16a: first extraction valve, 16b: second extraction valve, 16c: switching valve, 17, 17a, 17b: flow rate sensor, 20: control device, 20a: control panel, 21a: automatic extraction switch, 21b: manual extraction switch, 22a: washing water extraction switch, 22b: automatic washing switch.

Claims (5)

A diaphragm electrolyzer, a supply pipe for supplying water to be electrolyzed to each electrolysis chamber of the electrolyzer, and a pair of extraction pipes for extracting each electrolyzed water generated in each electrolyzer of the electrolyzer. An electrolyzed water generator comprising: a washing means having a washing pipe communicating with an upstream end of an electrolytically generated alkaline water extraction pipe and a washing pipe communicating with a downstream extraction port. The washing means, when the extraction from the electrolytically generated alkaline water extraction pipeline is stopped for a predetermined time, supplies the cleaning water to each of the cleaning pipelines, from the electrolytically generated alkaline water extraction pipeline. An electrolyzed water generating apparatus having a function of extracting water retained in the extraction pipe and then extracting the washing water. A diaphragm electrolyzer, a supply pipe for supplying water to be electrolyzed to each electrolysis chamber of the electrolyzer, and a pair of extraction pipes for extracting each electrolyzed water generated in each electrolyzer of the electrolyzer. An electrolyzed water generator comprising: a washing means having a washing pipe communicating with an upstream end of an electrolytically generated alkaline water extraction pipe and a washing pipe communicating with a downstream extraction port. The washing means, when the extraction from the electrolytically generated alkaline water extraction line has been stopped for a predetermined time, supplies the washing water to each of the cleaning lines, from the electrolytically generated alkaline water extraction line. An electrolyzed water generation apparatus having a function of simultaneously extracting the staying water in the extraction pipe and the washing water and the washing water for a longer time. The electrolyzed water generating apparatus according to claim 1, wherein the washing unit sets a time in which extraction from the electrolysis-generated alkaline water extraction line is stopped for a predetermined time as a standby time, and the standby time is the same as the electrolysis water. An electrolyzed water generator, wherein the water generator is set to be short during the day and long at night. 4. The electrolytic water generation apparatus according to claim 1, wherein the cleaning unit includes a flow rate sensor for cleaning water flowing through each of the cleaning conduits. 5. apparatus. The electrolyzed water generator according to any one of claims 1 to 4, wherein the electrolyzed water in the electrolyzed water generator uses general water as raw water, and the washing means includes the raw water and the electrolyzed water. Characterized in that one or both of them are used as washing water.

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