JP3835176B2 - Electrolyzed water generator - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to an electrolyzed water generating apparatus capable of continuously obtaining alkaline ionic water and acidic ionic water, and more particularly to a technique for efficiently discharging stagnant water inside a main body when use is interrupted.
[0002]
[Prior art]
Conventionally, as an electrolyzed water generating apparatus, after purifying raw water such as tap water in a septic tank, it is supplied to an electrolyte adding part and an electrolyte such as calcium salt is added, and further supplied to the electrolytic tank to be electrolyzed and acidified. There is one that generates ionic water or alkaline ionic water and discharges the generated ionic water to the outside of the apparatus.
[0003]
In such an electrolyzed water generating apparatus generally used in the past, after generating electrolyzed water, if the water remains in the electrolyzed water generating apparatus and left unused for a long time, The breeding of general bacteria is a concern due to the alteration of the accumulated water. In addition, when water stays in the electrolyte addition part, there is a problem that when the use of the electrolyzed water generating device is interrupted, the electrolyte is excessively dissolved in the water staying in the electrolyte addition part and the consumption of the electrolyte in the electrolyte addition part increases. .
[0004]
As a means for draining such accumulated water, an electromagnetic valve is provided at the lower part of the electrolytic cell, and when no water is supplied to the main body, the electromagnetic valve is opened to communicate with the drainage channel, There was something that discharged. In order to simplify the valve configuration and valve opening / closing control, it has also been proposed to use an opening / closing valve 12 as shown in FIGS.
[0005]
The on-off valve 12 shown here is provided in a drainage path for draining water staying in the electrolyzed water generating device, and pressures on the upstream side and downstream side of the drainage path in which the on-off valve 12 is provided. When the water is supplied from the outside into the electrolyzed water generator and the pressure on the upstream side of the drainage path is increased by the pressure of the supplied water, it is shown in FIG. When the upstream side pressure is reduced by stopping the supply of water as shown in FIG. 7, the valve is opened as shown in FIG.
[0006]
FIGS. 8 and 9 show an electrolyzed water generating apparatus 1 provided with such an on-off valve 12. The electrolyzed water generating apparatus 1 is formed with a drainage path communicating with an internal water flow path. The drainage path is constituted by a drainage introduction channel 29, a drainage main channel 30 and a drain pipe 31. This drainage path is drawn downward to the outside of the electrolyzed water generating apparatus 1, and the on-off valve 12 is disposed on the upstream side of the drainage introduction passage 29. In the electrolyzed water generating device 1 thus formed, the on-off valve 12 is opened when the supply of water to the electrolyzed water generating device 1 is stopped, and the accumulated water is automatically drained from the drainage path. It is what is said.
[0007]
However, when the on-off valve 12 is provided in the drainage path in this way, when water is supplied to the electrolyzed water generating device 1 and the on-off valve 12 is in the closed state, water stays in the drainage path due to surface tension. In this case, a negative pressure due to the head pressure of the water in the drainage path is applied to the downstream side of the on-off valve 12. In such a case, even if the supply of water to the electrolyzed water generating device 1 is stopped and the pressure on the upstream side of the on-off valve 12 decreases, the on-off valve 12 remains closed due to the negative pressure on the downstream side. It may be maintained and the accumulated water may not be drained.
[0008]
As a configuration for preventing such malfunction of the on-off valve 12, a configuration as shown in FIG. 10 has been proposed. In the electrolyzed water generating device 1 shown in FIG. 10, when electrolyzed water is generated, raw water is supplied from the water supply tap 33 to the water supply port 2 of the electrolyzed water generating device 1 through the water supply hose 32 and the water intake passage 3. Residual chlorine, musty odor, trihalomethane, agricultural chemicals, and the like are removed by the purification agent 4 in the adsorption purification tank 5 through the water flow path 3 from the inlet 42 to the water purification cartridge 40. Subsequently, it is filtered by passing through the filtration membrane 6 of the filtration tank 7 to remove fine turbidity, bacteria, and the like.
[0009]
The generated purified water flows out from the outlet 43 to the water supply channel 8, and at this time, the flow rate of the purified water in the water supply channel 8 is detected by the flow rate sensor 9, and the control power supply device 34 connects the electrodes 21 and 21. The application of voltage is started by automatic control.
[0010]
The purified water flowing through the water supply channel 8 flows into the branch water supply channel 13 and the branch drainage channel 11, and the purified water flowing into the branch drainage channel 11 reaches the upstream side of the on-off valve 12 and is opened and closed by its pressure. The valve 12 is closed, and the purified water does not flow to the drain introduction passage 29, and the water flow in the drainage path is stopped.
[0011]
On the other hand, the purified water that has flowed into the branch water supply channel 13 is supplied from the inflow port 44 to the electrolyte addition unit 14, and after the dissolved electrolyte is added into the electrolyte addition unit 14, the purified water is supplied from the outflow port 45 through the main supply path 18. Then, it is supplied from the inlet 46 to the electrode chambers 20 and 20 of the electrolytic cell 19.
[0012]
Then, by the electrolysis, alkaline ionized water is generated in the cathode chamber 20a of the electrode chambers 20 and 20, and acidic ionized water is generated in the anode chamber 20b. The alkaline ionized water generated in the cathode chamber 20a is discharged from the outlet 47 to the outside of the apparatus through the water discharge passage 23 and the discharge pipe 25 of the discharge nozzle 24. On the other hand, the acidic ionized water generated in the anode chamber 20b is discharged from the water discharge nozzle 56 to the outside of the apparatus through the water discharge channel 26 and the water discharge pipe 27. A part of the alkaline ionized water generated in the cathode chamber 20a flows into the main drainage flow path 30 through the bypass flow path 35 and is discharged from the drain pipe 31 to the outside of the apparatus.
[0013]
In such an electrolyzed water generating device 1, when the water supply to the electrolyzed water generating device 1 is stopped by closing the water supply tap 33, the flow of water in the water supply channel 8 is stopped and the flow rate sensor 9 is stopped. Detect water condition. At this time, application of a voltage between the electrodes 21 and 21 is stopped by automatic control.
[0014]
At this time, the pressure of the water flowing into the electrolyzed water generating device 1 from the water supply port 2 is not applied to the purified water flowing into the branch drainage flow path 11, thereby reducing the pressure on the upstream side of the on-off valve 12. As a result, the on-off valve 12 is opened. For this reason, the flow of water in the drainage path is released, and the water staying in the electrolyzed water generating apparatus 1 is drawn into the water flow in the drainage path and discharged below the electrolyzed water generating apparatus 1. .
[0015]
In such a draining operation, since the bypass channel 35 is connected to the downstream side of the on-off valve 12 in the drainage path, even if water is accumulated in the drainage path, negative pressure due to the water head pressure is generated. The pressure is relieved on the downstream side of the on-off valve 12, and malfunction of the on-off valve 12 is prevented.
[0016]
[Problems to be solved by the invention]
However, the configuration shown above is mainly for the case of using alkaline ionized water. However, when the electrolyzed water is generated by the electrolyzed water generating apparatus 1, a part of the alkaline ionized water is bypassed. 35, water is drained from the drainage path, and there is a problem that the discharge amount of alkaline ionized water discharged from the discharge channel 25 of the discharge channel 23 and the discharge nozzle 24 to the outside of the apparatus is reduced. .
[0017]
The present invention has been made in view of the above points, and electrolyzed water generation in which a drainage path for draining stagnant water is provided with an on-off valve that opens and closes depending on the pressure difference between the upstream side and the downstream side of the drainage path. In the device, the on / off valve can be prevented from opening / closing poorly and the stagnant water can be drained reliably, and the discharge amount of the alkaline ionic water and acidic ionic water to be mainly used is maintained sufficiently. It is an object of the present invention to provide an electrolyzed water generating apparatus capable of performing the above.
[0018]
[Means for Solving the Problems]
The electrolyzed water generating apparatus according to claim 1 of the present invention includes an electrolyte adding unit 14 for adding an electrolyte to the water supplied from the water supply port 2 and alkaline ionized water and acidic ions by electrolyzing the water to which the electrolyte has been added. An electrolytic tank 19 for generating water, a first water discharge path for discharging alkaline ionic water generated in the electrolytic tank 19 to the outside, and a first water discharge for discharging acidic ionic water generated in the electrolytic tank 19 to the outside. An electrolyzed water generating apparatus 1 having two water discharge paths, wherein water remaining inside is drained outward from the electrolyzed water generating apparatus 1 in a state where water supply from the water supply port 2 is stopped. The drainage path is provided with an on-off valve 12 that opens and closes according to the pressure difference between the upstream side and the downstream side of the drainage path. The on-off valve 12 is connected to the electrolyzed water generating device 1 from the water supply port 2. The pressure on the upstream side of the drainage channel is A bypass flow path that is closed when it becomes closed and is opened when the pressure on the upstream side is reduced by stopping the water supply, and connects the second water discharge path and the drainage path. 28 is provided such that the connecting position of the bypass flow path 28 in the drainage path is on the downstream side of the on-off valve 12.
[0019]
Moreover, the electrolyzed water generating apparatus according to claim 2 of the present invention includes an electrolyte adding unit 14 for adding an electrolyte to the water supplied from the water supply port 2, and electrolyzing the water to which the electrolyte has been added to cause alkaline ionized water and acidity. The electrolytic cell 19 for generating ionic water, the first water discharge path for discharging one of the alkaline ionic water and the acidic ionic water generated in the electrolytic cell 19 to the outside, and the electrolytic cell 19 In the electrolyzed water generating device 1 including a second water discharge path for discharging one of alkaline ionic water and acidic ionic water to the outside, in a state where water supply from the water supply port 2 is stopped A drainage path for draining water remaining inside from the electrolyzed water generator 1 downward is provided, and an opening / closing valve 12 is provided in the drainage path to open and close according to the pressure difference between the upstream side and the downstream side of the drainage path. , This on-off valve 12 When the pressure on the upstream side of the drainage path increases due to the supply of water from the water port 2 to the electrolyzed water generating device, the closed state is established. When the upstream side pressure is reduced by stopping the supply of water, the closed state is established. The bypass flow path 28 that is formed as described above and connects the second water discharge path and the drainage path is provided so that the connection position of the drainage path with the bypass flow path 28 is on the downstream side of the on-off valve 12. It is characterized by.
[0020]
In addition, the invention of claim 3 is the invention according to claim 1 or 2, wherein at least a part of the pipe line constituting the bypass flow path 28 has an inner diameter larger than that of the connection portion between the second water discharge path and the bypass flow path 28. It is formed so as to be smaller than the inner diameter of the pipe of the second water discharge path on the downstream side.
[0021]
The invention of claim 4 is characterized in that, in any one of claims 1 to 3, an air chamber 61 for holding air is provided downstream of the on-off valve 12 in the drainage path. .
[0022]
DETAILED DESCRIPTION OF THE INVENTION
Embodiments of the present invention will be described below.
[0023]
FIG. 1 shows a piping system diagram of the electrolyzed water generating apparatus 1. In addition, this electrolyzed water production | generation apparatus 1 is formed as an alkaline water production | generation apparatus for mainly utilizing alkaline ionized water among the electrolyzed water produced | generated.
[0024]
First, the structure of the electrolyzed water generating apparatus 1 will be described. As shown in FIG. 1, the electrolyzed water generating apparatus 1 includes a water purification cartridge 40, an electrolyte addition unit 14, an electrolytic tank 19, and an on-off valve 12.
[0025]
The water purification cartridge 40 purifies the introduced water, and is provided with an adsorption purification tank 5 filled with a purification agent 4 such as activated carbon or ion exchange resin, and disposed downstream of the adsorption purification tank 5, and is a hollow fiber membrane. And a filtration tank 7 in which a filtration membrane 6 such as a filter is installed.
[0026]
An inlet 42 of water to be supplied to the water purification cartridge 40 is formed at an upstream end (lower end in the drawing) of the adsorption purification tank 5 of the water purification cartridge 40, and a downstream end (see FIG. An outlet 43 for water led out from the water purification cartridge 40 is formed at the upper end portion.
[0027]
The electrolyte addition unit 14 includes an inner cylinder 15 that holds an electrolyte inside a cylindrical outer cylinder 41. The inner cylinder 15 includes calcium salts such as calcium chloride, calcium lactate, and calcium glycerophosphate. An electrolyte such as sodium chloride or potassium chloride is supplied. In the illustrated example, the electrolyte is supplied into the inner cylinder 15 by disposing a water-permeable bag 16 containing the electrolyte in the inner cylinder 15. An addition cylinder cap 17 is detachably attached to the upper opening of the outer cylinder 41. Here, the outer cylinder 41 and the addition cylinder cap 17 are fitted through an O-ring to form a watertight structure, and the fitting of the addition cylinder cap 17 is released to take out the inner cylinder 15 to remove the electrolyte. It can be refilled.
[0028]
An inlet 44 of water to be supplied to the electrolyte addition unit 14 is formed on the lower end surface of the outer cylinder 41 of the electrolyte addition unit 14. In addition, an outlet 45 of water led out from the electrolyte addition unit 14 is formed on the upper side surface of the outer cylinder 41 of the electrolyte addition unit 14.
[0029]
The inside of the electrolytic cell 19 is partitioned into two electrode chambers 20, 20 by an electrolytic diaphragm 22, and electrodes 21, 21 are disposed in the electrode chambers 20, 20, respectively. One electrode chamber 20 is formed as a cathode chamber 20a, and the other electrode chamber 20 is formed as an anode chamber 20b. An electrode 21 disposed in the cathode chamber 20a is formed as a cathode 21a, and an electrode disposed in the anode chamber 20b. 21 is formed as an anode 21b. Although not shown, a power source for applying a voltage between the electrodes 21 and 21 is connected to the electrodes 21 and 21 (21a and 21b).
[0030]
The on-off valve 12 is formed of a molded product of metal or resin, and as shown in FIGS. 6 and 7, an inflow opening 62 is provided at one end connected to the upstream side of the flow path, and is downstream of the flow path. An outflow opening 63 is formed at the other end connected to the side, and the inflow opening 62 and the outflow opening 63 communicate with a valve chamber 64 inside the on-off valve 12. A cylindrical valve seat 55 protrudes from the inner wall on the outflow opening 63 side in the valve chamber 64, and the inside of the valve seat 55 is formed as an outflow passage 69 communicating with the outflow opening 63. A coiled spring body 54 made of metal, resin, or the like is disposed around the valve seat 55 so as to surround the valve seat 55, and one end of the spring body 54 is a valve on the base side of the valve seat 55. It is in contact with the inner wall of the chamber 64. A valve body 53 is provided at the other end of the spring body 54 so as to face the opening of the valve seat 55. Here, the valve body 53 is provided with a circular holding rib 67 on one surface of the valve seat 55, and the other end of the spring body 54 is held inside the holding rib 67, whereby the spring body 54. A valve body 53 is provided at the other end. The valve body 53 is urged toward the side opposite to the opening side of the valve seat 55 in the valve chamber 64 by the elastic force of the spring body 54. A slight gap is formed between the outer peripheral edge of the valve body 53 and the inner peripheral wall of the valve chamber 64. In addition, the inside of the valve chamber 64 is divided into an inflow opening 62 side and an outflow opening 63 side by a partition wall 52 on the inflow opening 62 side of the valve body 53. The partition wall 52 is formed with a communication path 65 that communicates the inflow opening 62 side and the outflow opening 63 side in the valve chamber 64. 6 and 7, only one communication path 65 appears on the fractured surface of the partition wall 52, but usually a plurality of communication paths 65 are formed in the partition wall 52. The partition wall 52 has a plurality of protrusion-like support protrusions 66 formed on one surface of the outflow opening 63 side, and the valve body 53 biased toward the inflow opening 62 side by the elastic force of the spring body 54 is provided. It abuts on the support protrusion 66 and is supported in a state where there is a gap having the same dimension as the protrusion dimension of the support protrusion 66 between the partition wall 52 and the valve element 53.
[0031]
The on-off valve 12 automatically opens and closes according to the pressure difference between the inflow opening 62 side (upstream side) and the outflow opening 63 side (downstream side). That is, when a pressure higher than a certain level is applied to the water flowing into the valve chamber 64 from the inflow opening 62 and the pressure on the upstream side relative to the on-off valve 12 increases relative to the downstream side, the valve body 53 7 moves toward the valve seat 55 against the elastic force of the spring body 54 due to the pressure of water, and the valve body 53 is disposed so as to close the opening of the valve seat 55, and as shown in FIG. Is closed. On the other hand, when the pressure applied to the water flowing into the valve chamber 64 from the inflow opening 62 does not reach a certain value, and the pressure on the upstream side of the on-off valve 12 decreases relative to the downstream side, The valve body 53 moves to the inflow opening 62 side from the valve seat 55 by the elastic force of the spring body 54 and contacts the support protrusion 66 of the partition wall 52, so that the on-off valve 12 is opened as shown in FIG. . At this time, the water flowing into the valve chamber 64 from the inflow opening 62 flows into the gap between the partition wall 52 and the valve body 53 through the communication passage 65, and further, the outer peripheral edge of the valve body 53 and the inner peripheral wall of the valve chamber 64. Flows out of the on-off valve 12 from the outflow opening 63 through the outflow passage 69 of the valve seat 55.
[0032]
The piping configuration related to the electrolyzed water generating device 1 will be described. A water purification cartridge 40, an electrolyte adding unit 14, and an electrolyzer 19 are provided in series in a flow path of water supplied from the water supply port 2 into the electrolyzed water generating device 1. In addition, a first water discharge path and a second water discharge path for discharging the electrolyzed water to the outside of the electrolyzed water generating apparatus 1 are derived from the electrolytic tank 19. Further, a drainage path is provided from the water path between the water purification cartridge 40 and the electrolyte addition unit 14, and the on-off valve 14 is provided in this drainage path.
[0033]
More specifically, the water supply tap 33 such as a water tap and the water supply port 2 of the electrolyzed water generating apparatus 1 are connected by a water supply hose 32. Inside the apparatus, the upstream end of the intake channel 3 is connected to the water supply port 2, and the downstream end of the intake channel 3 is connected to the inlet 42 at the lower part of the adsorption purification tank 5 of the water purification cartridge 40. ing.
[0034]
A flow rate sensor 9 for measuring the flow rate of water in the water supply channel 8 is disposed in the middle of the piping of the water supply channel 8 led out from the outlet 43 of the filtration tank 7 of the water purification cartridge 40. The downstream side of the water supply channel 8 is branched into a branch water supply channel 13 and a branch drainage channel 11. The downstream side of the branch water supply channel 13 is connected to the inlet 44 on the lower surface of the electrolyte addition unit 14.
[0035]
On the other hand, the branch drainage flow path 11 is disposed so that the downstream side is directed downward, and the downstream end thereof is connected to the inflow opening 62 of the on-off valve 12. An upstream end of the drainage introduction channel 29 is connected to the outflow opening 63 of the on-off valve 12, and the drainage introduction channel 29 is disposed so that the downstream side is directed downward, and the downstream end is a main drainage stream. It is connected to the upstream end of the passage 30. The drainage main flow path 30 is composed of a substantially horizontal horizontal pipe part 30a formed on the upstream side and a substantially vertical vertical pipe part 30b formed downward from the downstream end of the horizontal pipe part 30a. It is formed by an L-shaped pipe line, and a drain pipe 31 is connected to its downstream end. As shown in FIG. 8, the drain pipe 31 is drawn downward to the outside of the electrolyzed water generating device 1. The branch drainage channel 11, the drainage introduction channel 29, the drainage main channel 30, and the drainage pipe 31 constitute a drainage channel.
[0036]
The main supply path 18 is led downward from the outlet 45 of the electrolyte addition unit 14, and the downstream end of the main supply path 18 is an inlet 46 formed on the lower surface of the electrolytic cell 19. Connected to each electrode chamber 20, 20.
[0037]
An outlet 47 that communicates with one electrode chamber 20 (cathode chamber 20a) and an outlet 48 that communicates with the other electrode chamber 20 (anode chamber 20b) are provided in the upper part of the electrolytic cell 19. From the outlet 47 communicating with one of the electrode chambers 20 (cathode chamber 20a), a water discharge passage 23 is led upward and connected to a discharge nozzle 24 provided on the upper surface of the electrolyzed water generating device 1. The discharge nozzle 24 is provided with a discharge pipe 25. The water discharge flow path 23 and the discharge pipe 25 of the discharge nozzle 24 constitute a first water discharge path for discharging alkaline ion water, which is mainly used electrolytic water, from the electrode chamber 20 (cathode chamber 20a). The supplied electrolyzed water (alkaline ion water) is discharged outside through the first water discharge path.
[0038]
Further, a water discharge passage 26 is led out downward from an outlet 45 communicating with the other electrode chamber 20 (anode chamber 20b), and a water discharge pipe 27 is connected to the downstream end of the water discharge passage 26. The water discharge pipe 27 is drawn outward from the lower part of the electrolyzed water generating device, and a water discharge nozzle 56 is provided at the downstream end of the water discharge pipe 27. The water discharge channel 26 and the water discharge pipe 27 constitute a second water discharge path for discharging acidic ion water which is electrolyzed water generated secondary, and this electrode chamber 20 (anode chamber 20b). The electrolyzed water (acidic ionic water) generated in is discharged outside through the second water discharge path.
[0039]
Further, a bypass channel 28 is provided between the second water discharge channel and the drainage channel. The bypass flow path 28 is connected to the connection position of the water discharge flow path 26 and the water discharge pipe 27 in the second water discharge path and the connection position of the drainage introduction flow path 29 and the drainage main flow path 30 in the drainage path, respectively. Yes.
[0040]
FIG. 8 shows the appearance of the electrolyzed water generating apparatus 1 as described above, and a drain pipe 31 constituting the downstream side of the drainage path is drawn out below the electrolyzed water generating apparatus 1. The opening 31 is disposed below the opening of the discharge pipe 25 of the discharge nozzle 24 constituting the first drainage path and the water discharge nozzle 56 constituting the downstream end of the second drainage path.
[0041]
Next, the usage method of the electrolyzed water generating apparatus 1 of the present invention and the flow of water in the apparatus will be described.
[0042]
First, the operation when electrolyzed water is generated by the electrolyzed water generator 1 will be described with reference to the piping system diagram of FIG. In the figure, the flow of water is indicated by solid arrows.
[0043]
First, the user operates a control panel provided on the outer surface of the apparatus to give an instruction to start clean water or set the quality of alkaline ionized water, and opens the water tap 33 to provide raw water such as tap water. Is supplied to the water supply port 2 of the electrolyzed water generating apparatus 1 through the water supply hose 32. At this time, the raw water sent to the water supply port 2 is sent from the inlet 42 to the water purification cartridge 40 through the intake passage 3, and residual chlorine, musty odor, trihalomethane, agricultural chemicals, etc. are removed by the purification agent 4 in the adsorption clarification tank 5. Is done. Subsequently, it is filtered by passing through the filtration membrane 6 of the filtration tank 7 to remove fine turbidity, bacteria, and the like. In this way, by filtering the raw water through the water purification cartridge 40, the raw water is subjected to a water purification treatment to produce purified water.
[0044]
The generated purified water flows out from the outlet 43 to the water supply channel 8, but passes through the flow sensor 9 when flowing through the water supply channel 8. When the flow sensor 9 detects purified water passing through the water supply channel 8, application of voltage between the electrodes 21 and 21 in the electrolytic cell 19 is started by automatic control.
[0045]
The purified water flowing through the water supply channel 8 flows into the branch water supply channel 13 and the branch drainage channel 11. At this time, the purified water flowing into the branch drainage channel 11 flows into the valve chamber 64 from the inflow opening 62 of the on-off valve 12, but the pressure of the water flowing into the electrolyzed water generating device 1 from the water supply port 2 is Therefore, this pressure causes the valve body 53 to move toward the outflow opening 63 against the elastic force of the spring body 54, so that the valve body 53 contacts the valve seat 55, and the outflow path 69 is The on-off valve 12 is closed as shown in FIG. For this reason, purified water does not flow from the branch drainage flow path 11 to the drainage introduction flow path 29, and the flow of water across the on-off valve 12 in the drainage path is stopped.
[0046]
On the other hand, the purified water that has flowed into the branch water supply channel 13 is supplied from the inlet 44 to the electrolyte addition unit 14, and the dissolved electrolyte is applied to the electrolyte addition unit 14. The purified water provided with the electrolyte is supplied from the outlet 45 through the main supply path 18 to the electrode chambers 20 and 20 of the electrolytic cell 19 from the inlet 46. At this time, after the purified water is supplied to the position where the outlet 45 is formed, the purified water flows out from the outlet 45 in the electrolyte adding section 14 and stays in the electrolyte adding section 14 to some extent, so that the electrolyte is sufficient. The purified water given to is discharged from the electrolyte addition unit 14.
[0047]
Then, by the electrolysis, alkaline ionized water is generated in the cathode chamber 20a of the electrode chambers 20 and 20, and acidic ionized water is generated in the anode chamber 20b. The alkaline ionized water generated in the cathode chamber 20a flows from the outlet 47 into the first water discharge path constituted by the water discharge flow path 23 and the discharge pipe 25 of the discharge nozzle 24, and is discharged outside the apparatus. On the other hand, the acidic ion water generated in the anode chamber 20b is discharged from the water discharge nozzle 56 to the outside of the apparatus through the second water discharge path constituted by the water discharge flow path 26 and the water discharge pipe 27. A part of the acidic ion water flowing through the second water discharge path flows into the drain main flow path 30 through the bypass flow path 28 and is discharged from the drain pipe 31 to the outside of the apparatus.
[0048]
Next, the operation when the supply of water into the apparatus is stopped will be described. FIG. 2 shows a piping system diagram when water supply is stopped.
[0049]
When water supply to the electrolyzed water generating device 1 is stopped by the user closing the water supply tap 33, the flow of water in the water supply flow path 8 is stopped, and the flow sensor 9 detects the water stop state. At this time, by automatic control, a reverse voltage is applied between the electrodes 21 and 21 as necessary to remove the scale on the surfaces of the electrodes 21 and 21, and then the electrode 21 is connected to the electrodes 21 and 21 in the electrolytic cell 19. The voltage application is stopped.
[0050]
At this time, the pressure of the water flowing into the electrolyzed water generating device 1 from the water supply port 2 is not applied to the purified water flowing into the branch drainage flow path 11, so that the valve body 53 of the on-off valve 12 is a spring body. The valve body 53 is moved away from the valve seat 55 by the elastic force of 54 to the inflow opening 62 side, and the on-off valve 12 is opened as shown in FIG. For this reason, the flow of water in the drainage path is released, and the water staying in the electrolyzed water generating apparatus 1 is discharged below the electrolyzed water generating apparatus 1 through the drainage path. At this time, the purified water staying in the electrolyte addition unit 14 is drawn into the water flow flowing through the drainage path, flows backward through the branch water supply channel 13 through the inlet 44 and flows into the drainage path, and the electrolyzed water passes through the drainage path. It is discharged from the generator 1. Also, the electrolyzed water (alkaline ion water and acid ion water) staying in the electrode chambers 20, 20 of the electrolysis tank 19 is drawn into the water flow flowing into the drainage path from the electrolyte addition unit 14 via the branch water supply channel 13. As a result, the main supply path 18 flows backward from the inlet 46, flows into the drainage path via the electrolyte addition unit 14 and the branch water supply path 13, and is discharged below the electrolyzed water generating apparatus 1. At this time, the electrolyzed water (alkaline ion water) staying in the first drainage channel also flows backward and is drawn into one of the electrode chambers 20 (cathode chamber 20a) of the electrolytic cell 19, and similarly electrolyzed from the drainage channel. The water is discharged below the water generating device 1. At this time, when air flows in from the end opening of the discharge pipe 25, the water draining operation as described above is performed smoothly. Furthermore, the electrolyzed water (acidic ion water) staying in the second drainage channel and the bypass channel 28 is drawn into the water flow flowing through the drainage channel and flows into the drainage channel, and the electrolyzed water generating device 1 through the drainage channel. Discharged from.
[0051]
Here, in the electrolyzed water generating apparatus 1 having the above-described configuration, a part of the electrolyzed water is drained from the bypass channel 28 through the drainage channel when the electrolyzed water is generated, but the bypass channel 28 is acidic. Because it is connected to the second water discharge path for discharging ionic water, the alkaline ionic water used mainly is not drained from the drainage path, and a sufficient discharge amount of alkaline ionic water is ensured. It is something that can be done. In consideration of the case of using acidic ionic water, part of the acidic ionic water flows into the bypass flow path 28 and the rest is discharged from the water discharge nozzle 56 of the second water discharge path.
[0052]
Further, when the drainage operation as described above is performed, the drainage path is open to the outside air via the bypass flow path 28 and the second water discharge path, so that when the drainage operation is started, the drainage path Even if water is present in the drainage introduction channel 29, the drainage main channel 30 and the drainage pipe 31 constituting the portion downstream of the on-off valve 12, the negative pressure applied to the downstream side of the on-off valve 12 due to the water head pressure. Pressure is relieved. Therefore, the valve body 53 of the on-off valve 12 is not drawn into the negative pressure of water existing in the drainage introduction passage 29, the drainage main passage 30 and the drainage pipe 31, and is not separated from the valve seat 55. When the pressure of water flowing into the electrolyzed water generating device 1 from the water supply port 2 is no longer applied to the purified water flowing into the flow path 11, the on-off valve 12 is reliably opened, and the electrolyzed water generating device 1 The accumulated water can be drained reliably. At this time, since the bypass flow path 28 is formed so as to branch from the second water discharge path, by forming the bypass flow path 28 as short as possible, the drainage path becomes the bypass flow path 28 and the second water discharge path. Can be released to the outside air through a short path, and further, a small amount of water staying in the bypass flow path 28 and the second drainage path is quickly drained from the drainage path. The drainage channel is opened directly to the outside air without passing through the bypass channel 28 and the second drainage channel, and thereby, the negative pressure due to the water head pressure in the drainage channel can be efficiently relieved. It is.
[0053]
Further, even if the negative pressure applied to the on-off valve 12 is relieved in this way, a certain amount of negative pressure is applied to the on-off valve 12, but in the pipeline on the downstream side of the on-off valve 12 in the drainage path. If an air chamber 61 having a structure for holding air is provided in the air chamber 61, even if a negative pressure is applied to the on-off valve 12 due to the head pressure of water in the drainage passage, the air chamber 61 opens and closes by a buffering action due to expansion and contraction of the air in the air chamber 61 The valve 12 can be more reliably opened. That is, the pressure of the water flowing into the electrolyzed water generating device 1 from the water supply port 2 is not applied to the purified water flowing into the branch drainage flow path 11, and the pressure on the upstream side of the drainage path sandwiching the on-off valve 12 is small. When this happens, there is room for the valve body 53 of the on-off valve to move toward the inflow opening 62 (upstream side) due to the expansion of the air in the air chamber 61, and the on-off valve 12 can be more reliably opened. Is. In the example shown in FIG. 5, the drainage main flow path 30 constituting the drainage path is partially bulged upward at the connection portion between the horizontal pipe portion 30 a and the vertical pipe portion 30 b, and this bulge portion is formed as the air chamber 61. For this reason, even if water is present in the drain main flow path 30, the air is held in the air chamber 61.
[0054]
In the embodiment shown in FIG. 3, the electrode polarity of the electrodes 21, 21 is arbitrarily switched as a power source for applying a voltage between the electrodes 21, 21 disposed in the electrode chambers 20, 20 of the electrolytic cell 19. A control power supply 34 is provided. Other configurations are the same as those shown in FIGS.
[0055]
In generating electrolyzed water in such an electrolyzed water generating apparatus 1, when mainly using alkaline ionized water, the electrode disposed in the electrode chamber 20 on the side connected to the first water discharge path A voltage is applied between the electrodes 21 and 21 so that the electrode 21 disposed in the electrode chamber 20 on the side connected to the second water discharge path is the anode, and the electrode 21 and 21 are electrically connected. By the decomposition, alkaline ionized water is generated in the electrode chamber 20 in which the electrode 21 serving as the cathode is disposed, and acidic ionized water is generated in the electrode chamber 20 in which the electrode 21 serving as the anode is disposed. The And the alkaline ionized water mainly used flows into the 1st water discharge path comprised from the water discharge flow path 23 and the discharge pipe 25 of the discharge nozzle 24 from the outlet 47, and is discharged outside the apparatus, On the other hand, The generated acidic ion water is discharged from the water discharge nozzle 56 to the outside of the apparatus through the second water discharge path constituted by the water discharge flow path 26 and the water discharge pipe 27. A part of the acidic ion water flowing through the second water discharge path flows into the drain main flow path 30 through the bypass flow path 28 and is discharged from the drain pipe 31 to the outside of the apparatus.
[0056]
When acid ion water is mainly used, the electrode 21 disposed in the electrode chamber 20 on the side connected to the first water discharge path is the anode and the side connected to the second water discharge path. A voltage is applied between the electrodes 21 and 21 so that the electrode 21 disposed in the electrode chamber 20 becomes a cathode. At this time, the electrode 21 that has become the cathode is disposed by electrolysis. Alkaline ionized water is generated in the electrode chamber 20, and acidic ionized water is generated in the electrode chamber 20 in which the electrode 21 serving as an anode is disposed. And the acidic ion water mainly utilized flows into the 1st water discharge path | route comprised from the water outlet flow path 23 and the discharge pipe 25 of the discharge nozzle 24 from the outflow port 47, and is discharged outside the apparatus, On the other hand, The generated alkaline ionized water is discharged from the water discharge nozzle 56 to the outside of the apparatus through the second water discharge path constituted by the water discharge channel 26 and the water discharge pipe 27. A part of the alkaline ionized water flowing through the second water discharge path flows into the drain main flow path 30 through the bypass flow path 28 and is discharged from the drain pipe 31 to the outside of the apparatus.
[0057]
Also in the electrolyzed water generating apparatus 1 having such a configuration, part of the electrolyzed water is drained from the bypass channel 28 through the drainage channel when the electrolyzed water is generated. Because it is connected to the path, one of the generated alkaline ionic water and acidic ionic water that is mainly used is not drained from the drainage path, and the discharge amount of the electrolytic water that is mainly used is reduced. It can be sufficiently secured. In consideration of the case of using the other electrolyzed water, a part of the other electrolyzed water is allowed to flow into the bypass channel 28 and the rest is discharged from the water discharge nozzle 56 of the second water discharge path. Yes.
[0058]
In the embodiment shown in FIGS. 1 and 2 and the embodiment shown in FIG. 3, the electrolyzed water mainly used is discharged from the first water discharge path among the alkaline ionized water and the acidic ionized water that are generated electrolyzed water. However, in consideration of the case where the electrolyzed water generated as a secondary is also used, it is preferable to ensure a sufficient discharge amount of the electrolyzed water discharged from the second water discharge path. As described above, in order to sufficiently secure the discharge amount of the electrolyzed water discharged from the second water discharge path, at least a part of the pipes constituting the bypass flow path 28 has an inner diameter that is equal to the second water discharge path. Of the water discharge pipe 27 constituting the downstream portion of the connecting portion with the bypass flow path 28 is formed so as to be smaller than the inner diameter of the water discharge pipe 27 so that the electrolysis that flows through the bypass flow path 28 when the electrolyzed water is generated. It is preferable to reduce the flow rate of water as much as possible. Here, in the present invention, since the bypass path 28 is formed so as to branch from the second drainage path, the inner diameter of the pipeline of the second drainage path and the pipeline of the bypass path 28 are thus formed. By controlling the inner diameter, the flow rate of the electrolyzed water flowing through the bypass channel 28 can be easily controlled with a simple configuration when the electrolyzed water is generated.
[0059]
For example, in the example shown in FIG. 4, the rib 60 that protrudes inwardly is formed on the inner peripheral surface of a part of the pipe of the bypass flow path 28 over the entire circumference, thereby the pipe of the bypass flow path 28. An orifice (throttle mechanism) is formed inside, and a portion where the inner diameter becomes smaller than the inner diameter of the water discharge pipe 27 is formed. The inner diameter of the portion of the bypass channel 28 that is smaller than the inner diameter of the water discharge pipe 27 is preferably in the range of 1/6 to 1/4 of the inner diameter of the water discharge pipe 27. .
[0060]
Here, in order to reduce the flow rate of the bypass channel 28, when a portion having a small inner diameter is formed in the bypass channel 28, when alkaline ionized water flows through the bypass channel 28, the bypass channel 28 is bypassed by deposits such as calcium carbonate. Although there is a possibility that the flow path 28 may be clogged, in the case of the embodiment shown in FIGS. 1 and 2, or in the case of using mainly alkaline ionized water in the embodiment shown in FIG. Since it is acidic water, such deposits are not deposited in the bypass channel 28, and the circulation of the bypass channel 28 can be maintained for a long time.
[0061]
【The invention's effect】
As described above, the electrolyzed water generating device according to claim 1 of the present invention includes an electrolyte adding unit that adds an electrolyte to water supplied from a water supply port, and alkaline ionized water obtained by electrolyzing water to which the electrolyte is added. An electrolytic cell for generating acidic ionic water, a first water discharge path for discharging alkaline ionic water generated in the electrolytic cell to the outside, and a second for discharging acidic ionic water generated in the electrolytic cell to the outside An electrolyzed water generating device comprising a water discharge path, wherein a drainage path is provided for draining water remaining inside downward to the outside in a state where water supply from the water supply port is stopped. An on-off valve that opens and closes according to the pressure difference between the upstream side and the downstream side of the drainage path is provided, and the pressure on the upstream side of the drainage path increases due to the supply of water to the electrolyzed water generator from the water supply opening. Sometimes closes and water supply stops When the pressure on the upstream side is reduced, the bypass channel connects the second water discharge channel and drainage channel, and the bypass channel connection position in the drainage channel opens and closes. Since water is supplied from the water supply port, the pressure of water flowing into the electrolyzed water generator from the water supply port is upstream of the on-off valve in the drainage path when water is supplied from the water supply port. When the on / off valve is closed and the drainage of the accumulated water from the drainage path is stopped and the supply of water from the water supply port is stopped, the electrolyzed water is generated upstream of the on / off valve in the drainage path. The pressure of water flowing into the device is no longer applied, the on-off valve is opened, the flow of water in the drainage channel is opened, and the water remaining in the electrolyzed water generator is drawn into the water flow in the drainage channel And drain from the drainage channel One in which it is bet. In addition, the drainage path will be opened to the outside air via the bypass and the second water discharge path, even when water is present downstream from the on / off valve of the drainage path when the drainage operation is started, When the water head pressure relaxes the negative pressure applied to the downstream side of the on-off valve and the pressure of water flowing into the electrolyzed water generator from the water supply port is no longer applied to the upstream side of the on-off valve, the on-off valve It is surely opened, and the accumulated water in the electrolyzed water generator can be drained reliably. Furthermore, when the electrolyzed water is generated, a part of the electrolyzed water is drained from the drainage path via the bypass path, but the bypass path is connected to the second water discharge path, and the second water discharge path is connected. Since a part of the circulating acidic ionic water is drained from the drainage path, the amount of water discharged from the first water discharge path of the alkaline ionic water mainly used can be sufficiently secured.
[0062]
Moreover, the electrolyzed water generating apparatus according to claim 2 of the present invention includes an electrolyte adding unit for adding an electrolyte to water supplied from a water supply port, and alkaline ionic water and acidic ionic water by electrolyzing water to which the electrolyte has been added. A first water discharge path for discharging one of alkaline ionic water and acidic ionic water generated in the electrolytic cell to the outside, alkaline ionic water generated in the electrolytic cell and acidic An electrolyzed water generating device comprising a second water discharge path for discharging one of the ionic waters to the outside, and electrolyzing water remaining inside when water supply from the water supply port is stopped A drainage path for draining outward from the water generator is provided, and an on-off valve that opens and closes according to the pressure difference between the upstream side and the downstream side of the drainage path is provided on the drainage path. To the electrolyzed water generator When the pressure on the upstream side of the drainage path increases due to water, the second water discharge path is formed so that it is closed when the pressure on the upstream side decreases due to the water supply being stopped. When the water is supplied from the water supply port, the bypass channel that connects the drainage channel with the bypass channel is located on the downstream side of the on-off valve. On the upstream side of the on-off valve in the drainage path, the pressure of the water flowing into the electrolyzed water generator from the water supply port is applied, the on-off valve is closed, and the drainage of the accumulated water from the drainage path is stopped, When the supply of water is stopped, the pressure of the water flowing into the electrolyzed water generating device is not applied upstream of the on-off valve in the drainage passage, and the on-off valve is opened and the water in the drainage passage is opened. Distribution is opened and electrolyzed water Water remaining in the formed in the apparatus is drawn into the water flow of the waste water path, in which can be drained from the drain path. In addition, the drainage path will be opened to the outside air via the bypass and the second water discharge path, even when water is present downstream from the on / off valve of the drainage path when the drainage operation is started, When the water head pressure relaxes the negative pressure applied to the downstream side of the on-off valve and the pressure of water flowing into the electrolyzed water generator from the water supply port is no longer applied to the upstream side of the on-off valve, the on-off valve It is surely opened, and the accumulated water in the electrolyzed water generator can be drained reliably. Furthermore, when the electrolyzed water is generated, a part of the electrolyzed water is drained from the drainage path via the bypass path, but the bypass path is generated because it is connected to the second water discharge path. Discharge mainly the electrolyzed water of alkaline ionized water and acidic ionized water through the first water discharge path and discharge the secondary generated water through the second water discharge path. Thus, a part of this electrolyzed water can be drained from the drainage path from the second water discharge path through which the secondary electrolyzed water flows, The amount of water discharged from the first water discharge path can be sufficiently secured.
[0063]
Further, the invention of claim 3 is the invention according to claim 1 or 2, wherein at least a part of the pipe line constituting the bypass flow path has an inner diameter downstream of a connection portion between the second water discharge path and the bypass flow path. Therefore, the flow rate of the electrolyzed water flowing from the second water discharge path to the bypass path can be suppressed, and the second water discharge path When it is going to use also the electrolyzed water produced | generated secondary from discharged | emitted from that, the discharge amount can fully be ensured.
[0064]
According to a fourth aspect of the present invention, in any one of the first to third aspects, an air chamber for holding air is provided in the drainage path downstream of the on-off valve, so that water is supplied from the water supply port. When the pressure of the water flowing into the electrolyzed water generating device is no longer applied to the upstream side of the on-off valve in the drainage path, a negative pressure is applied to the downstream side of the on-off valve due to the head pressure of water in the drainage path However, the on-off valve can be more reliably opened by the buffering action by the expansion and contraction of the air in the air chamber.
[Brief description of the drawings]
FIG. 1 is a schematic cross-sectional view showing an operation in an example of an embodiment of the present invention.
FIG. 2 is a schematic cross-sectional view showing another operation of the above.
FIG. 3 is a schematic sectional view showing an operation in another example of the embodiment of the present invention.
FIG. 4 is a partial cross-sectional view of the above.
FIG. 5 is a cross-sectional view of another part of the above.
FIG. 6 is a partially broken front view showing an example of the on-off valve.
FIG. 7 is a partially broken front view showing another operation of the above.
FIG. 8 is a front view showing the appearance of the electrolyzed water generating device.
FIG. 9 is a schematic view showing a part of a drainage path.
FIG. 10 is a schematic cross-sectional view showing a conventional technique.
[Explanation of symbols]
1 Electrolyzed water generator
2 Water inlet
12 On-off valve
14 Electrolyte addition part
19 Electrolysis tank
28 Bypass channel
61 Air chamber

Claims (4)

An electrolyte addition unit that adds an electrolyte to water supplied from a water supply port, an electrolytic cell that electrolyzes water added with an electrolyte to generate alkaline ionized water and acidic ionized water, and an electrolytic cell An electrolyzed water generating apparatus comprising a first water discharge path for discharging alkaline ionic water to the outside and a second water discharge path for discharging acidic ionic water generated in an electrolytic cell to the outside, from a water supply port When the water supply of the water is stopped, a drainage path is provided to drain the water remaining inside to the outside, and the drainage path is opened and closed according to the pressure difference between the upstream side and the downstream side of the drainage path. An on-off valve is provided, and the on-off valve is closed when the pressure on the upstream side of the drainage path increases due to the supply of water from the water supply port to the electrolyzed water generating device. Open when it gets smaller The bypass flow path that connects the second water discharge path and the drainage path is provided so that the connection position of the bypass path in the drainage path is on the downstream side of the on-off valve. An electrolyzed water generator. An electrolyte addition unit that adds an electrolyte to water supplied from a water supply port, an electrolytic cell that electrolyzes water added with an electrolyte to generate alkaline ionized water and acidic ionized water, and an electrolytic cell A first water discharge path for discharging one of alkaline ionized water and acidic ionized water to the outside, and a second for discharging one of the other of alkaline ionized water and acidic ionized water generated in the electrolytic cell to the outside An electrolyzed water generating device having a water discharge path, wherein the water remaining inside is drained outwardly from the electrolyzed water generating device in a state where water supply from the water supply port is stopped. This drainage path is provided with an on-off valve that opens and closes according to the pressure difference between the upstream side and the downstream side of the drainage path, and this on-off valve is provided on the upstream side of the drainage path by supplying water to the electrolyzed water generator from the water supply port. Pressure increases A bypass channel that is formed so as to be opened when the upstream side pressure is reduced due to the water supply being stopped and the second water discharge path and the drainage path communicate with each other. An electrolyzed water generating device, characterized in that a connection position with a bypass flow path in a path is provided downstream of an on-off valve. The inner diameter of at least part of the pipes constituting the bypass flow path is smaller than the inner diameter of the pipes of the second water discharge path on the downstream side of the connection portion between the second water discharge path and the bypass flow path. The electrolyzed water generating device according to claim 1, wherein the electrolyzed water generating device is formed as described above. The electrolyzed water generating device according to any one of claims 1 to 3, wherein an air chamber for holding air is provided in the drainage path downstream of the on-off valve.

Images